Risk of Internal Cancers from Arsenic in Drinking Water.The U.S. Environmental Protection Agency Environmental Protection Agency (EPA), independent agency of the U.S. government, with headquarters in Washington, D.C. It was established in 1970 to reduce and control air and water pollution, noise pollution, and radiation and to ensure the safe handling and is under a congressional mandate to revise its current standard for arsenic arsenic (är`sənĭk), a semimetallic chemical element; symbol As; at. no. 33; at. wt. 74.9216; m.p. 817°C; (at 28 atmospheres pressure); sublimation point 613°C;; sp. gr. (stable form) 5.73; valence −3, 0, +3, or +5. in drinking water drinking water supply of water available to animals for drinking supplied via nipples, in troughs, dams, ponds and larger natural water sources; an insufficient supply leads to dehydration; it can be the source of infection, e.g. leptospirosis, salmonellosis, or of poisoning, e.g. . We present a risk assessment for cancers of the bladder, liver, and lung from exposure to arsenic in water, based on data from 42 villages in an arseniasis-endemic region of Taiwan. We calculate excess lifetime risk estimates for several variations of the generalized linear model Not to be confused with general linear model. In statistics, the generalized linear model (GLM) is a useful generalization of ordinary least squares regression. It relates the random distribution of the measured variable of the experiment (the and for the multistage-Weibull model. Risk estimates are sensitive to the model choice, to whether or not a comparison population is used to define the unexposed disease mortality rates, and to whether the comparison population is all of Taiwan or just the southwestern region. Some factors that may affect risk could not be evaluated quantitatively: the ecologic nature of the data, the nutritional status nutritional status, n the assessment of the state of nourishment of a patient or subject. of the study population, and the dietary intake of arsenic. Despite all of these sources of uncertainty, however, our analysis suggests that the current standard of 50 [micro]g/L is associated with a substantial increased risk of cancer and is not sufficiently protective of public health. Key words: bladder cancer bladder cancer Malignant tumour of the bladder. The most significant risk factor associated with bladder cancer is smoking. Exposure to chemicals called arylamines, which are used in the leather, rubber, printing, and textiles industries, is another risk factor. , generalized linear model, lifetime death risk, lung cancer lung cancer, cancer that originates in the tissues of the lungs. Lung cancer is the leading cause of cancer death in the United States in both men and women. Like other cancers, lung cancer occurs after repeated insults to the genetic material of the cell. , margin of exposure, multistage-Weibull. Environ en·vi·ron tr.v. en·vi·roned, en·vi·ron·ing, en·vi·rons To encircle; surround. See Synonyms at surround. [Middle English envirounen, from Old French environner Health Perspect 108:655-661(2000). [Online 5 June 2000] http://ehpnet1.niehs.nih.gov/docs/2000 /108p655-661morales/abstract.html A metal found in rocks and mineral formations in the earth's crust crust Outermost solid part of the Earth, essentially composed of a range of igneous and metamorphic rock types. In continental regions, the crust is made up chiefly of granitic rock, whereas the composition of the ocean floor corresponds mainly to that of basalt and gabbro. , arsenic has long been associated with the development of cancer in humans. Exposure can occur via inhalation inhalation /in·ha·la·tion/ (in?hah-la´shun) 1. the drawing of air or other substances into the lungs.inhala´tional 2. the drawing of an aerosolized drug into the lungs with the breath. 3. , primarily in industrial settings, or through ingestion ingestion /in·ges·tion/ (-chun) the taking of food, drugs, etc., into the body by mouth. in·ges·tion n. 1. The act of taking food and drink into the body by the mouth. 2. . Because drinking water is one of the primary routes of exposure, standards set in 1942 established a maximum contaminant level Maximum Contaminant Levels are standards that are set by the United States Environmental Protection Agency (EPA) for drinking water quality. A Maximum Contaminant Level (MCL) is the legal threshold limit on the amount of a hazardous substance that is allowed in drinking water under (MCL MCL - Macintosh Common LISP ) of 50 [micro]g/L in drinking water. In 1975, 50 [micro]g/L was adopted as the interim standard in response to the 1974 Safe Drinking Water Act The Safe Drinking Water Act (SDWA) is a United States federal law passed by the U.S. Congress on December 16, 1974. It is the main federal law that ensures safe drinking water for Americans. (1). In a 1984 health assessment, the U.S. Environmental Protection Agency (EPA EPA eicosapentaenoic acid. EPA abbr. eicosapentaenoic acid EPA, n.pr See acid, eicosapentaenoic. EPA, n. ) classified arsenic as a class A human carcinogen carcinogen: see cancer. carcinogen Agent that can cause cancer. Exposure to one or more carcinogens, including certain chemicals, radiation, and certain viruses, can initiate cancer under conditions not completely understood. , based primarily on epidemiologic ep·i·de·mi·ol·o·gy n. The branch of medicine that deals with the study of the causes, distribution, and control of disease in populations. [Medieval Latin epid evidence, and produced quantitative risk estimates for both ingestion and inhalation routes of exposure (2). Although the EPA assessment for the inhalation route is well accepted, the risk assessment for ingestion remains controversial. The 1984 risk assessment for arsenic in drinking water was based on an epidemiologic study epidemiologic study A study that compares 2 groups of people who are alike except for one factor, such as exposure to a chemical or the presence of a health effect; the investigators try to determine if any factor is associated with the health effect in Taiwan that examined an association between arsenic exposure via drinking water and skin cancer (non-melanoma) (3). EPA investigators estimated that the lifetime risk of skin cancer for individuals who consumed 2 L water per day at 50 [micro]g/L could be as high as 2 in 1,000. This high value prompted questions about the 1984 risk assessment, including applicability of the risk assessment to the U.S. population, the role of arsenic as an essential nutrient An essential nutrient is a nutrient required for normal body functioning that cannot be synthesized by the body and must be obtained from a dietary source. Some categories of essential nutrient include vitamins, dietary minerals, essential fatty acids, and essential amino acids. , the relevance of skin lesions Skin Lesions Definition A skin lesion is a superficial growth or patch of the skin that does not resemble the area surrounding it. Description Skin lesions can be grouped into two categories: primary and secondary. as the basis for the risk assessment, and the role of arsenic intake via food. In 1988, the EPA Risk Assessment Forum published a revised skin cancer risk assessment and focused attention on these questions (4). The EPA is currently under a congressional mandate to finalize fi·nal·ize tr.v. fi·nal·ized, fi·nal·iz·ing, fi·nal·iz·es To put into final form; complete or conclude: "They have jointly agreed ... a new rule for arsenic in drinking water by 1 January 2001 (5). There has been substantial focus on the association between arsenic and skin cancer, and there is also substantial evidence that exposure to arsenic in drinking water increases the mortality risk for several internal cancers. Increases in bladder and lung cancer mortality were found in a region of northern Chile (6). An association was also found between bladder cancer mortality and arsenic in drinking water in Argentina (7). Significant increased mortality was observed for males and females in Taiwan due to lung, liver, skin, kidney, and bladder cancer (8). The National Research Council presents a more detailed summary of the evidence linking arsenic exposure to internal cancer (1). The purpose of this article is to present a risk assessment for mortality due to several internal cancers based on a reanalysis of the data reported by Chen et al. (8). Brown (9) discussed the limitations of the data available for analysis when the current EPA risk assessment (4) was prepared. For several reasons, it can be argued that the risk assessment of internal cancers presented in this paper yields more convincing results than the previous EPA assessment based on skin cancer. First, the current study focuses on mortality from bladder, lung, and liver cancers Liver Cancer Definition Liver cancer is a relatively rare form of cancer but has a high mortality rate. Liver cancers can be classified into two types. identified through national death records. In addition, unlike the Tseng et al. (3) study that was used in the EPA analysis, which grouped data into three broad exposure intervals [low ([is less than] 300 [micro]g/L), medium (300-600 [micro]g/L), and high ([is greater than] 600 [micro]g/L)], data now available provide exposure at the individual village level. This paper is a follow-up to a preliminary study that focused only on bladder cancer and examined model sensitivity (10). The current analysis is expanded to include lung and liver cancers and examines issues of dose-response modeling by Poisson regression In statistics, the Poisson regression model attributes to a response variable Y a Poisson distribution whose expected value depends on a predictor variable x, typically in the following way: Materials and Methods Internal cancer data. Data used in this analysis were derived from a study in an arseniasis-endemic area of Taiwan (11-13). Cancer mortality data were collected from death certificates of residents of 42 villages during 1973-1986. These data were originally collected in 1987, so only records up to 1986 were available. Causes of death were classified according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the Eighth Revision of International Classification of Diseases, 1965 Revision (ICD ICD International Classification of Diseases (of the World Health Organization); intrauterine contraceptive device. ICD abbr. ) (14). The data consisted of person-years at risk and the number of deaths due to bladder (ICD code 188), lung (ICD code 162), and liver (ICD code 155) cancer in 5-year age increments for both males and females. Table 1 summarizes the internal cancer data and provides person-years at risk and observed number of cancer deaths by age, sex, and arsenic level. Although individual village arsenic levels are available and will be used in subsequent analyses, exposure levels are grouped in Table 1 for convenience of presentation. The numbers of bladder, liver, and lung cancers are given, along with the number of person-years at risk. For example, males between the ages of 50 and 69 contributed 21,040 person-years at risk and 6, 17, and 12 deaths were observed from bladder, liver, and lung cancer, respectively. Table 1. Person-years at risk by age, sex, and arsenic level with observed number of deaths from cancer (bladder, liver, and lung).
Age (years)(a)
Sex, arsenic
level ([micro]g/L) 20-30 30-49 50-69
Male
< 100 35,818 34,196 21,040
(0, 0, 0) (1, 10, 2) (6, 17, 12)
100-299 18,578 16,301 10,223
(0, 0, 0) (0, 4, 3) (7, 15, 14)
300-599 27,556 25,544 15,747
(0, 3, 0) (5, 7, 9) (15, 23, 30)
[is greater than 16,609 15,773 8,573
or equal to] 600 (0, 0, 1) (4, 12, 3) (15, 15, 23)
Total 98,561 91,814 55,583
(0, 3, 1) (10, 33, 17) (43, 70, 79)
Female
< 100 27,901 32,471 21,556
(0, 0, 0) (3, 1, 5) (9, 6, 18)
100-299 13,381 15,514 11,357
(0, 0, 0) (0, 3, 4) (9, 6, 10)
300-599 19,831 24,343 16,881
(0, 0, 0) (0, 5, 6) (19, 6, 20)
[is greater than 12,988 15,540 9,084
or equal to] 600 (0, 0, 0) (0, 4, 6) (21, 7, 28)
Total 74,101 87,868 58,878
(0, 0, 1) (3, 13, 21) (58, 25, 76)
Age (years)(a)
Sex, arsenic [is greater than
level ([micro]g/L) or equal to] 70 Total
Male
< 100 4,401 95,455
(10, 4, 14) (17, 31, 28)
100-299 2,166 47,268
(2, 4, 13) (9, 23, 30)
300-599 3,221 72,068
(12, 6, 14) (32, 39, 53)
[is greater than 1,224 42,179
or equal to] 600 (8, 2, 6) (27, 29, 33)
Total 11,012 256,970
(32, 16, 47) (85, 122, 144)
Female
< 100 5,047 86,975
(9, 5, 5) (21, 12, 29)
100-299 2,960 43,212
(2, 5, 5) (11, 14, 19)
300-599 3,848 64,903
(11, 2, 10) (30, 13, 36)
[is greater than 1,257 38,869
or equal to] 600 (7, 1, 4) (28, 12, 38)
Total 13,112 233,959
(29, 13, 24) (90, 51, 122)
(a) Values in parentheses See parenthesis. parentheses - See left parenthesis, right parenthesis. are number of deaths from bladder, liver, and lung cancer, respectively. Exposure data. Drinking water samples were collected from wells of 42 villages in 1964-1966 (12). The artesian wells wells made by boring into the earth till the instrument reaches water, which, from internal pressure, flows spontaneously like a fountain. They are usually of small diameter and often of great depth. See also: Artesian were gradually closed; the last one closed in mid-1970. Although mortality data were collected for a later time period (1973-1986), it is likely that arsenic levels in well water remained relatively unchanged over this time period. It could also be argued that because of the long latency (1) The time between initiating a request in the computer and receiving the answer. Data latency may refer to the time between a query and the results arriving at the screen or the time between initiating a transaction that modifies one or more databases and its completion. of the cancers of interest, it is appropriate for exposure to be based on a time period 10 to 20 years before death. A strength of the currently available exposure data is that individual well concentration levels are available for each village. Physical and chemical characteristics of drinking water such as pH value and levels of arsenic, sodium, calcium, magnesium magnesium (măgnē`zēəm, –zhəm), metallic chemical element; symbol Mg; at. no. 12; at. wt. 24.305; m.p. about 648.8°C;; b.p. about 1,090°C;; sp. gr. 1.738 at 20°C;; valence +2. , manganese manganese (măng`gənēs, măn`–) [Lat.,=magnet], metallic chemical element; symbol Mn; at. no. 25; at. wt. 54.938; m.p. about 1,244°C;; b.p. about 1,962°C;; sp. gr. 7.2 to 7. , iron, mercury, chromium chromium (krō`mēəm) [Gr.,=color], metallic chemical element; symbol Cr; at. no. 24; at. wt. 51.996; m.p. about 1,857°C;; b.p. 2,672°C;; sp. gr. about 7.2 at 20°C;; valence +2, +3, +6. , lead, nitrite nitrite Any salt or ester of nitrous acid (HNO2). The salts are inorganic compounds with ionic bonds, containing the nitrite ion (NO2−) and any cation. and nitrate nitrate, chemical compound containing the nitrate (NO3) radical. Nitrates are salts or esters of nitric acid, HNO3, formed by replacing the hydrogen with a metal (e.g., sodium or potassium) or a radical (e.g., ammonium or ethyl). nitrogen, fluoride fluoride, a salt of hydrofluoric acid; see hydrogen fluoride. See also fluoridation; fluorine. , and bicarbonate bicarbonate or hydrogen carbonate, chemical compound containing the bicarbonate radical, -HCO3. The most familiar of such compounds is sodium bicarbonate (baking soda). See carbonate. have been intensively studied in both Blackfoot disease-endemic and -nonendemic areas (15,16). Arsenic level was the only level that was significantly higher than the maximal max·i·mal adj. 1. Of, relating to, or consisting of a maximum. 2. Being the greatest or highest possible. allowable limit and strikingly different in water from shallow wells and artesian wells. The data also have some limitations. The drinking water was not tested for levels of dissolved dis·solve v. dis·solved, dis·solv·ing, dis·solves v.tr. 1. To cause to pass into solution: dissolve salt in water. 2. radon and other [Alpha]-emitters. Fluorescent fluorescent having the quality of fluorescence. fluorescent antibody see fluorescence microscopy. fluorescent antibody test see fluorescence microscopy. compounds, especially humic acids Noun 1. humic acid - a dark brown humic substance that is soluble in water only at pH values greater than 2; "the half-life of humic acid is measured in centuries" humic substance - an organic residue of decaying organic matter , have been found in the well water. These fluorescent substances result from the decomposition decomposition /de·com·po·si·tion/ (de-kom?pah-zish´un) the separation of compound bodies into their constituent principles. de·com·po·si·tion n. 1. of organic matter, particularly dead plants. However, it is unlikely that their presence causes confounding confounding when the effects of two, or more, processes on results cannot be separated, the results are said to be confounded, a cause of bias in disease studies. confounding factor in this analysis because widespread contamination is not confined con·fine v. con·fined, con·fin·ing, con·fines v.tr. 1. To keep within bounds; restrict: Please confine your remarks to the issues at hand. See Synonyms at limit. to the arseniais-endemic area. Standardized mortality ratio The standardized mortality ratio or SMR in epidemiology is the ratio of observed deaths to expected deaths according to a specific health outcome in a population and serves as an indirect means of adjusting a rate. . We used standardized mortality ratios (SMRs) to summarize sum·ma·rize intr. & tr.v. sum·ma·rized, sum·ma·riz·ing, sum·ma·riz·es To make a summary or make a summary of. sum the observed patterns of mortality in data. SMRs provide a popular approach to comparing mortality in a specific population with mortality from a suitable comparison population (17). SMRs correspond to ratios of observed and expected number of events and are calculated by [Sigma][O.sub.i]/[Sigma][E.sub.i], where [O.sub.i] is the observed number of deaths in the ith age group and [E.sub.i] is the corresponding expected number of deaths, calculated by multiplying the study population size ([P.sub.i]) by the age-specific cancer death rate ([M.sub.i]) in a comparison population (i.e., [E.sub.i] = [P.sub.i] x [M.sub.i]). Usually SMRs are expressed as a percentage so that the value 100 x [Sigma][O.sub.i]/[Sigma][E.sub.i] is the number reported. There are concerns with using all of Taiwan as a comparison population because of the potential for bias associated with differences in the populations (e.g., rural vs. urban). For this reason, we considered two comparison populations in this analysis: all of Taiwan and the southwestern region of Taiwan (18). The latter is expected to provide a more suitable comparison basis for the study population, which is largely rural and fairly poor. Table 2 contains the data from the two comparison populations. The number of deaths due to bladder, lung, and liver cancers and person years at risk (PYR PYR Pyrrolidonyl Aminopeptidase PYR Per Your Request PYR Prior Year Report ) were extracted by age group and sex for 1973-1986.
Table 2. Comparison population data, 1973-1986.
All Taiwan
Sex, Deaths (n)
age
(years) PYR Bladder Lung Liver
Male
20-25 13,271,386 3 45 206
25-30 11,054,191 4 86 426
30-35 8,628,516 8 144 782
35-40 6,793,545 20 217 1,351
40-45 6,375,466 50 447 2,030
45-50 6,384,052 91 951 3,145
50-55 6,062,515 164 1,852 4,140
55-60 5,018,542 213 2,882 4,562
60-65 3,666,535 345 3,557 4,030
65-70 2,443,367 413 3,569 3,259
70-75 1,480,126 418 2,658 2,107
75-80 720,375 305 1,318 1,170
80-85 287,294 146 512 436
85+ 105,411 66 152 188
Female
20-25 12,612,276 0 39 81
25-30 10,548,089 2 70 134
30-35 8,210,507 2 102 168
35-40 6,458,620 5 205 247
40-45 5,802,856 20 365 396
45-50 5,157,821 41 525 590
50-55 4,335,755 76 730 763
55-60 3,517,193 124 1,018 1,018
60-65 2,776,622 153 1,224 1,039
65-70 2,106,715 173 1,280 1,039
70-75 1,490,659 185 1,062 875
75-80 888,468 157 707 602
80-85 433,245 81 330 300
85+ 217,590 41 136 153
Southwestern region
Sex, Deaths (n)
age
(years) PYR Bladder Lung Liver
Male
20-25 2,956,638 2 14 43
25-30 2,175,046 3 26 88
30-35 1,580,019 2 33 140
35-40 1,320,637 6 38 245
40-45 1,327,866 18 89 403
45-50 1,334,769 34 181 565
50-55 1,214,443 52 323 716
55-60 977,820 61 478 832
60-65 739,460 103 595 722
65-70 520,965 126 607 704
70-75 320,158 130 465 463
75-80 158,750 88 230 246
80-85 63,236 32 80 103
85+ 22,651 15 22 33
Female
20-25 2,595,529 0 7 15
25-30 1,846,189 2 19 34
30-35 1,402,764 0 17 39
35-40 1,215,899 2 41 53
40-45 1,191,615 8 75 75
45-50 1,111,810 14 112 138
50-55 957,985 36 160 169
55-60 774,836 52 200 255
60-65 634,758 77 258 243
65-70 492,203 68 230 235
70-75 342,767 70 190 199
75-80 199,630 43 108 127
80-85 96,293 21 45 59
85+ 46,089 9 10 31
PYR, person-years. Data from the Department of Health (18). Generalized linear model. Poisson modeling is often used in epidemiologic analysis, particularly for rare events such as cancer deaths. In fact, SMRs can correspond to maximum likelihood estimates of risk ratios from a Poisson model (17). In our analysis, we assumed that the number of deaths due to cancer follows a Poisson distribution A statistical method developed by the 18th century French mathematician S. D. Poisson, which is used for predicting the probable distribution of a series of events. For example, when the average transaction volume in a communications system can be estimated, Poisson distribution is used with parameter equal to the person-years at risk multiplied by the hazard of dying of cancer. The hazard is often modeled as a function of age (t) and exposure (x). As described by Breslow and Day (17), a broad class of models can be characterized char·ac·ter·ize tr.v. character·ized, character·iz·ing, character·iz·es 1. To describe the qualities or peculiarities of: characterized the warden as ruthless. 2. using the following general form, [1] h(x,t) = [h.sub.0](t) x g(x), where [h.sub.0](t) denotes the baseline hazard function that only depends on age, t, and describes the instantaneous in·stan·ta·ne·ous adj. 1. Occurring or completed without perceptible delay: Relief was instantaneous. 2. hazard of dying of cancer for the unexposed population. The risk ratio attributed to exposure level x is denoted by g(x). Of course, it is likely that a variety of factors, including cigarette smoking, use of bottled water, and dietary intake of inorganic inorganic /in·or·gan·ic/ (in?or-gan´ik) 1. having no organs. 2. not of organic origin. in·or·gan·ic n. 1. arsenic, could influence or even confound con·found tr.v. con·found·ed, con·found·ing, con·founds 1. To cause to become confused or perplexed. See Synonyms at puzzle. 2. the model. The model described in Equation 1 will allow consideration of other covariates. Unfortunately, measurements for these and other potentially important factors were not available for our study. Rather, this is an ecologic study wherein where·in adv. In what way; how: Wherein have we sinned? conj. 1. In which location; where: the country wherein those people live. 2. only relatively simple exposure and population characteristics could be measured. It will be important to consider this and other sources of uncertainty when interpreting the results. Although not discussed extensively here, it is possible for the risk ratio g(x) to also depend on age, t. For example, older people may be more susceptible to exposure. We did in fact explore such age-dependent risk models and found that in general, it was adequate to model the relative risk as a function of exposure only. A wide range of models was obtained by varying a) the use of comparison populations; b) the way age is modeled in [h.sub.0](t), e.g., linear, quadratic quadratic, mathematical expression of the second degree in one or more unknowns (see polynomial). The general quadratic in one unknown has the form ax2+bx+c, where a, b, and c are constants and x is the variable. , or the use of regression splines; c) transformations of exposure concentrations; and d) the way exposure is modeled. Table 3 summarizes the various modeling options considered in this analysis. Each model corresponds to choosing one option from each column. For example, the model excluding the comparison population, with a linear age effect, an exponential 1. (mathematics) exponential - A function which raises some given constant (the "base") to the power of its argument. I.e. f x = b^x If no base is specified, e, the base of natural logarthims, is assumed. 2. linear dose effect, and no transformation on dose, is characterized by [h.sub.0](t) = exp exp abbr. 1. exponent 2. exponential ([[Alpha].sub.0] + [[Alpha].sub.1]t) and g(x) = exp([[Beta].sub.1]x). Note that the linear and quadratic dose-effect models (generally referred to as additive additive In foods, any of various chemical substances added to produce desirable effects. Additives include such substances as artificial or natural colourings and flavourings; stabilizers, emulsifiers, and thickeners; preservatives and humectants (moisture-retainers); and models) do not fit into the usual class of generalized linear models (GLMs) and require special programming. Exponential linear and exponential quadratic models fall under the general class of multiplicative mul·ti·pli·ca·tive adj. 1. Tending to multiply or capable of multiplying or increasing. 2. Having to do with multiplication. mul models. The spline In computer graphics, a smooth curve that runs through a series of given points. The term is often used to refer to any curve, because long before computers, a spline was a flat, pliable strip of wood or metal that was bent into a desired shape for drawing curves on paper. See Bezier and B-spline. age effect was modeled using natural splines because of the ease of obtaining predicted values (19). There are three options for the baseline hazard: model the hazard without including a comparison population, treat the comparison population as an unexposed group, or replace the baseline hazard function with empirical estimates based on the comparison population (not included in Table 1). The third option can be accomplished by fitting a Poisson model containing indicators corresponding to the age categories observed in the comparison population. This approach essentially corresponds to the traditional SMR (Specialized Mobile Radio) The communications services used by police, ambulances, taxicabs, trucks and other delivery vehicles. Throughout the U.S., approximately 3,000 independent operators are licensed by the FCC to offer this service, which provides always-on approach. Because there were no villages with zero concentration levels, the method used to model the baseline hazard had a fairly strong influence on the results. In particular, the choice of whether to include a comparison population had a strong influence. The use of an unexposed comparison population has the potential to provide more information about the shape of the model at low concentrations.
Table 3. Poisson modeling options.
Comparison
population Age effect [h.sub.0](t)
None Linear
exp([[Alpha].sub.0] + [[Alpha].sub.1] t)
Southwestern Quadratic
Taiwan exp([[Alpha].sub.0] + [[Alpha].sub.1]t +
[[Alpha].sub.2][t.sup.2])
All of Regression spline
Taiwan exp[[[Alpha].sub.0] + [[Alpha].sub.1]ns(t)](b)
Comparison
population Dose transformation
None Linear
x = ppb(a)
Southwestern Logarithmic
Taiwan x = log(1 + ppb)
All of Square root
Taiwan x = [square root of ppb]
Comparison
population Dose effect g(x)
None Linear
[[Beta].sub.1]x
Southwestern Quadratic
Taiwan [[Beta].sub.1]x + [[Beta].sub.2][x.sup.2]
All of Exponential linear
Taiwan exp([[Beta].sub.1]x)
Exponential quadratic
exp([[Beta].sub.1]x + [[Beta].sub.2][x.sup.2])
(a) Represents exposure concentration in parts per billion, which is equivalent to micrograms per liter liter, abbr. l, unit of volume in the metric system, defined since 1964 as equal to 0.001 cubic meters, or 1 cubic decimeter. A cube that has each of its edges equal to 10 centimeters has a volume of 1 liter. The liter is equal to 1.057 liquid quarts, 0. . (b) ns(t) represents a natural spline applied to t. Although not a member of the usual GLM GLM Global Language Monitor GLM Global Marine (stock symbol) GLM Graduated Length Method (ski instruction) GLM Good Looking Mom (used in pediatric practices) GLM God Loves Me class, the MSW model was also considered because it was used in the previous risk assessment (4). The MSW corresponds to letting g(x) = [[Beta].sub.0] + [[Beta].sub.1]x + [[Beta].sub.2][x.sup.2] and [h.sub.0](t) = C [(t - [T.sub.0]).sub.+] (10), where t denotes age and x denotes exposure concentration. The plus sign (+) indicates a truncation on the (t - [T.sub.0]) term (i.e., if [T.sub.0] [is greater than] t then the term is set to zero). Results based on the MSW model are only presented for comparison. The GLM approach has several advantages over the MSW model. First, the MSW model appears to be more sensitive to outliers than the GLM model (10). Also, the hazard function for the MSW model involves a truncation in t that complicates estimation. Finally, the inclusion of the power parameter k (for our purposes, k = 2) tends to give the fitted model a relatively sublinear shape that leads, in general, to higher benchmark doses than the GLM models. Quantitative risk assessment. Because the risk of dying from cancer is age dependent, it is common to base risk assessment on the excess risk of dying from cancer over the course of a typical lifetime. The adjusted lifetime death risk can be calculated by integrating the death hazard over the typical lifetime in the population of interest, [MATHEMATICAL EXPRESSION A group of characters or symbols representing a quantity or an operation. See arithmetic expression. NOT REPRODUCIBLE IN ASCII ASCII or American Standard Code for Information Interchange, a set of codes used to represent letters, numbers, a few symbols, and control characters. Originally designed for teletype operations, it has found wide application in computers. ] where S(t) is the probability of surviving until age t and h(x,t) is the hazard for dying of the cancer of interest at age t for someone exposed at level x. Applying integration by parts In calculus, and more generally in mathematical analysis, integration by parts is a rule that transforms the integral of products of functions into other, hopefully simpler, integrals. The rule arises from the product rule of differentiation. , ldr(x) can also be written as [MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] where [Lambda]k(t) denotes the hazard of dying at age t from causes other than the cancer of interest. This function can be approximated by [MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] where [MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] denotes the sum over all 5-year age groups in the study and [q.sub.t] is the probability of dying during the 5-year time interval indicated by t. Values for [q.sub.t] were taken from the 1996 U.S. population lifetable for males and females (Table 4) (20). Table 4. U.S. death probabilities by age and sex, 1996.
Probability of
death ([q.sub.t])
Age (years) Male Female
20-25 0.00742 0.00239
25-30 0.00755 0.00307
30-35 0.00962 0.00423
35-40 0.01227 0.00595
40-45 0.01621 0.00834
45-50 0.02182 0.01224
50-55 0.03144 0.01938
55-60 0.04622 0.02938
60-65 0.06966 0.04577
65-70 0.09278 0.06417
70-75 0.12183 0.09207
75-80 0.14149 0.12267
80-85 0.15457 0.16036
85+ 0.24949 0.41813
Data from Vital Statistics of the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. , 1996 (20). Traditionally, standards for carcinogenic carcinogenic having a capacity for carcinogenesis. compounds have been set by finding the exposure level that yields a rate of [10.sup.-6] over background. As suggested by Brown (9) and discussed by Smith and Sharp (21), this estimate is probably unreliable for epidemiologic data, where exposure is not typically measured accurately enough to extrapolate extrapolate - extrapolation to such low risk levels. The new EPA guidelines guidelines, n.pl a set of standards, criteria, or specifications to be used or followed in the performance of certain tasks. for cancer risk assessments (22) suggest the use of a point-of-departure analysis for settings where the mode of action is supportive of linearity or there is insufficient support for a nonlinear A system in which the output is not a uniform relationship to the input. nonlinear - (Scientific computation) A property of a system whose output is not proportional to its input. mode of action. The idea is to estimate a point on the exposure response curve within the observed range of the data and then extrapolate linearly to lower doses. The dose associated with 10% excess risk ([ED.sub.10]) is the standard point of departure, but often in epidemiologic studies, an excess risk of 10% is fairly large and occurs only at relatively high doses. We will use both 1% and 5% excess risks for the point of departure ([ED.sub.01] and [ED.sub.05], respectively). We computed confidence intervals confidence interval, n a statistical device used to determine the range within which an acceptable datum would fall. Confidence intervals are usually expressed in percentages, typically 95% or 99%. for excess lifetime risk using the Delta method In statistics, the delta method is a method for deriving an approximate probability distribution for a function of an asymptotically normal statistical estimator from knowledge of the limiting variance of that estimator. (23). Bootstrap See boot. (operating system, compiler) bootstrap - To load and initialise the operating system on a computer. Normally abbreviated to "boot". From the curious expression "to pull oneself up by one's bootstraps", one of the legendary feats of Baron von Munchhausen. methods were also used for models with nonparametric age effects, yielding similar results (24). The new guidelines also suggest a margin-of-exposure analysis (MOE Moe continually exasperated at Larry and Curly for their mischievous pranks. [TV: “The Three Stooges” in Terrace, II, 366] See : Exasperation ), defined as the point of departure divided by the environmental exposure of interest. This approach is the proposed default mode of action when linearity is not the most reasonable assumption (22). For subsequent discussion we will use [MOE.sub.01] (50) to represent the margin of exposure using the [ED.sub.01] point of departure and 50 [micro]g/L as the environmental exposure of interest. Results Table 5 contains a descriptive summary of the internal cancer data, showing person-years at risk, observed number of cancers, and the SMRs for age, sex, and exposure grouped into the same intervals used by the EPA in the skin cancer risk assessment. As in Wu et al. (12), the analysis is limited to persons [is greater than or equal to] 20 years of age because there were essentially no cancer deaths observed in those younger than 20 years of age. Note that the entire Taiwanese population was used to calculate the expected deaths used in the computation Computation is a general term for any type of information processing that can be represented mathematically. This includes phenomena ranging from simple calculations to human thinking. of SMRs in Table 5. Although the computed SMRs display a large amount of noise, there appear to be higher SMRs at high exposure levels compared to exposures in the lower range, especially for bladder and lung cancer. There is no observed tendency in SMRs with respect to age, which suggests no age dependency on the risk ratio, g(x), defined in Equation 1. Overall, females have higher SMRs than males. Liver cancer mortality is generally higher than expected, although there is no particularly strong exposure-response relationship.
Table 5. Summary statistics.
Observed no.
of cancer
deaths
(SMR(a) x 100)
Villages (n) PYR(b) Bladder
Overall 42 490,929 175 (1,327)
Exposure ([micro]g/L)
0-50 8 92,920 26 (1,002)
50-100 6 102,797 12 (415)
100-200 4 40,679 12 (1,047)
200-300 3 36,514 8 (766)
300-400 4 28,870 6 (744)
400-500 3 28,655 22 (2,968)
500-600 7 79,446 34 (1,490)
600+ 7 81,048 55 (3,271)
Age (years)
20-40 42 258,789 2 (1,446)
40-60 42 164,549 21 (730)
60+ 42 67,591 121 (1,189)
Sex
Male 42 256,970 85 (1,005)
Female 42 233,959 90 (1,904)
Observed no. of cancer deaths
(SMR(a) x 100)
Lung Liver Combined
Overall 266 (266) 173 (134) 614 (254)
Exposure ([micro]g/L)
0-50 30 (156) 29 (118) 85 (183)
50-100 31 (143) 18 (65) 61 (116)
100-200 21 (243) 19 (174) 52 (251)
200-300 24 (308) 14 (144) 46 (247)
300-400 12 (197) 6 (77) 24 (163)
400-500 21 (365) 12 (160) 55 (393)
500-600 56 (332) 34 (159) 124 (306)
600+ 71 (514) 41 (217) 167 (486)
Age (years)
20-40 5 (178) 18 (169) 25 (184)
40-60 116 (365) 76 (130) 213 (228)
60+ 145 (222) 79 (133) 345 (256)
Sex
Male 144 (220) 122 (127) 351 (206)
Female 122 (354) 51 (158) 263 (368)
(a) Definition from Breslow and Day (17). (b) 1973-1986. The GLM analysis began by fitting all possible models and comparing the Akaike information criterion Akaike's information criterion, developed by Hirotsugu Akaike under the name of "an information criterion" (AIC) in 1971 and proposed in Akaike (1974), is a measure of the goodness of fit of an estimated statistical model. It is grounded in the concept of entropy. (AIC AIC Association des Infermières Canadiennes. ) to narrow the model choice (25). The AIC is a commonly used criterion for comparing nonnested models. It penalizes the model deviance Conspicuous dissimilarity with, or variation from, customarily acceptable behavior. Deviance implies a lack of compliance to societal norms, such as by engaging in activities that are frowned upon by society and frequently have legal sanctions as well, for example, the by adding twice the number of parameters to it. Thus a model with a low AIC will be one that describes the observed data well (a low deviance) yet with relatively few parameters (small penalty). The models with the lowest AIC provide the best fit. Because it was not appropriate to compare AIC for the models based on different data sets, we provide separate analyses with and without comparison populations. Table 6 identifies models 1-9 and the MSW model that appear in Tables 7-10 and Figures 1-3. For simplicity we will refer to the model numbers. Table 7 compares the four top performing models based on AIC for the models with and without comparison populations for male bladder cancer. Several other models fit reasonably well, but we chose to present only four (see "Discussion"). It is important to note, however, that models including exposure concentration were highly significant compared to models excluding concentration. We also present the MSW model. Although detailed results are shown here only for male bladder cancer, the same general patterns apply to females and to all cancer outcomes except for the combined analysis (see "Discussion"). In general, models with no transformation on dose and an exponential linear dose effect fit well when we used no comparison population. When we used population data from the southwestern region of Taiwan or the entire Taiwanese population, models with the square root and log transformation fit well. This is most likely due to the relatively low cancer death rates in the comparison population. The log-transformation allowed the fitted curve fitted curve see fitted curve. to rise more quickly from zero to accommodate this difference. Using the log-transformation without the comparison population gave a good model fit, according to AIC, but risk estimates were not easy to interpret because of instability of the fitted model at low dose. For this reason, we chose not to pursue the log-transformation without the comparison population any further. A few additive models gave a good fit, but in most cases, the multiplicative models did a better job, so we chose not to continue with the additive models. Also note that the MSW model fit reasonably well (Figures 1-3 show graphical representations). Each dot in Figures 1-3 corresponds to the estimated lifetime risk of dying of bladder cancer for villages, grouped by 50-[micro]g/L exposure levels (0-50, 50-100, etc.). The grouping is for presentation purposes only because village-specific estimates were highly variable. The idea of grouping for the purpose of graphical presentation of a fitted model has been widely used in the logistic regression In statistics, logistic regression is a regression model for binomially distributed response/dependent variables. It is useful for modeling the probability of an event occurring as a function of other factors. context as well (26). Fitted curves for the models without the comparison population are very similar in shape, whereas there is a considerable amount of variability in the models with a comparison population.
Table 6. Model description.
Dose Dose Age
Model transformation effect(a) effect
1 Identity Linear Quadratic
2 Identity Linear Spline
3 Identity Quadratic Spline
4 Log Linear Quadratic
5 Log Quadratic Quadratic
6 Log Quadratic Spline
7 Sqrt Linear Quadratic
8 Sqrt Quadratic Quadratic
9 Sqrt Quadratic Spline
MSW Identity Quadratic Truncated
(a) Exponential linear or exponential quadratic.
Table 7. AIC for best-fitting models.
All of Southwestern
Model None Taiwan area
1 302.1655 -- --
2 302.5547 -- --
3 -- 334.8289 326.9948
4 302.9700 -- 326.6287
5 -- 330.0863 --
6 303.3353 330.9968 --
7 -- -- 326.1207
8 -- -- 327.1098
9 -- 333.8307 --
MSW 302.0293 348.4275 334.3308
Tables 8-10 contain risk statistics for the best-fitting GLM models and the MSW model with and without comparison population data. Concentrations are reported in U.S. equivalent concentrations of arsenic in drinking water, based on conversions that account for the average weight and average water intake for a male living in the United States compared to a male living in Taiwan. For models 1 and 2, which have no transformation on dose, [ED.sub.01] estimates equal 595 and 351 [micro]g/L, respectively, for male bladder cancer. For models 3, 4, and 5, which have a log-transformed dose effect, [ED.sub.01] estimates for male bladder cancer range from 21 to 54 [micro]g/L. Models 7 and 8, which have a square root dose effect, give higher estimates (156 and 108 [micro]g/L, respectively). Results for model 9 are similar to models 7 and 8. When a comparison population is used (Tables 9 and 10), there is more variability in the predicted lifetime risk from model to model. It appears that the inclusion of a large unexposed comparison population had a relatively strong influence on estimation of risk. Estimates of [ED.sub.01] and [ED.sub.05] based on using the southwestern region of Taiwan tended to be much lower than those based on using the Taiwanese-wide population. The MSW model implies a lower risk when no comparison population was used ([ED.sub.01] = 633 [micro]g/L for male bladder cancer) compared to estimates when a comparison population is used (164 and 185 [micro]g/L). Table 8. Concentrations ([micro]g/L) for different measures of risk (without comparison population).
Bladder Lung
Model no.(a) M F M F
1(b)
[ED.sub.01] 395 252 364 258
[LED.sub.01] 326 211 294 213
[MOE.sub.01](50) 7.9 5.0 7.3 5.2
[ED.sub.05] 1,277 813 1,345 885
[LED.sub.05] 1,076 690 1,086 733
[MOE.sub.05](50) 25.54 16.3 26.9 17.7
2(d)
[ED.sub.01] 351 244 343 256
[LED.sub.01] 296 209 279 215
[MOE.sub.01](50) 7.0 4.9 6.9 5.1
[ED.sub.05] 1,181 796 1,288 879
[LED.sub.05] 1,005 683 1,045 735
[MOE.sub.05](50) 23.6 15.9 25.8 17.6
MSW(e)
[ED.sub.01] 633 365 227 396
[MOE.sub.01](50) 12.7 7.3 4.5 7.9
[ED.sub.05] 1,439 828 1,171 898
[MOE.sub.05](50) 28.8 16.6 23.4 18.0
Liver Combined
Model no.(a) M F M F
1(b)
[ED.sub.01] 573 673 169 121
[LED.sub.01] 437 410 148 105
[MOE.sub.01](50) 11.5 13.5 3.4 2.4
[ED.sub.05] -(c) - 720 493
[LED.sub.05] - - 629 430
[MOE.sub.05](50) - - 14.4 9.9
2(d)
[ED.sub.01] 585 657 164 120
[LED.sub.01] 451 405 144 106
[MOE.sub.01](50) 11.7 13.1 3.3 2.4
[ED.sub.05] - - 703 492
[LED.sub.05] - - 617 433
[MOE.sub.05](50) - - 14.1 9.8
MSW(e)
[ED.sub.01] 864 824 163 267
[MOE.sub.01](50) 17.3 16.5 3.3 5.3
[ED.sub.05] - - 706 605
[MOE.sub.05](50) - - 14.1 12.1
(a) Dose transformation, dose effect, and age effect, respectively. (b) Identity, linear, and quadratic. (c) [ED.sub.05] outside the observable ob·serv·a·ble adj. 1. Possible to observe: observable phenomena; an observable change in demeanor. See Synonyms at noticeable. 2. range of data. (d) Identity, linear, and spline. (e) Identity, quadratic, and truncated truncated adjective Shortened . Table 9. Concentrations ([micro]g/L) for different measures of risk (with Taiwanese comparison population).
Bladder Lung
Model no.(a) M F M F
3(b)
[ED.sub.01] 22 21 11 8
[LED.sub.01] 18 17 8 6
[MOE.sub.01](50) 0.4 0.4 0.2 0.2
[ED.sub.05] 504 330 1,145 448
[LED.sub.05] 355 248 514 280
[MOE.sub.05](50) 10.1 6.6 22.9 9.0
5(d)
[ED.sub.01] 23 19 11 8
[LED.sub.01] 19 16 8 6
[MOE.sub.01](50) 0.5 0.4 0.2 0.2
[ED.sub.05] 539 304 1,276 476
[LED.sub.05] 380 231 564 274
[MOE.sub.05](50) 10.8 6.1 25.5 9.5
6(e)
[ED.sub.01] 41 17 128 33
[LED.sub.01] 18 9 42 10
[MOE.sub.01](50) 0.8 0.3 2.6 0.7
[ED.sub.05] 611 293 925 491
[LED.sub.05] 416 185 684 346
[MOE.sub.05](50) 12.2 5.9 18.5 9.8
9(f)
[ED.sub.01] 100 72 76 68
[LED.sub.01] 65 52 32 34
[MOE.sub.01](50) 2.0 1.4 1.5 1.4
[ED.sub.05] 708 407 978 579
[LED.sub.05] 516 309 659 433
[MOE.sub.05](50) 14.2 8.1 19.6 11.6
MSW(g)
[ED.sub.01] 164 88 196 116
[MOE.sub.01](50) 3.3 1.8 3.9 2.3
[ED.sub.05] 852 455 1,014 579
[MOE.sub.05](50) 17.0 9.1 20.3 11.6
Liver Combined
Model no.(a) M F M F
3(b)
[ED.sub.01] 254 331 3 2
[LED.sub.01] 54 63 3 2
[MOE.sub.01](50) 5.1 6.6 0.1 0.0
[ED.sub.05] -(c) - 111 54
[LED.sub.05] - - 76 42
[MOE.sub.05](50) - - 2.2 1.1
5(d)
[ED.sub.01] 239 339 3 2
[LED.sub.01] 51 65 3 2
[MOE.sub.01](50) 4.8 6.8 0.1 0.0
[ED.sub.05] - - 113 56
[LED.sub.05] - - 77 43
[MOE.sub.05](50) - - 2.3 1.1
6(e)
[ED.sub.01] 608 404 86 9
[LED.sub.01] 337 87 35 3
[MOE.sub.01](50) 12.2 8.1 1.7 0.2
[ED.sub.05] - - 389 125
[LED.sub.05] - - 278 75
[MOE.sub.05](50) - - 7.8 2.5
9(f)
[ED.sub.01] 895 511 45 17
[LED.sub.01] 542 148 19 10
[MOE.sub.01](50) 17.9 10.2 0.9 0.3
[ED.sub.05] - - 499 228
[LED.sub.05] - - 337 160
[MOE.sub.05](50) - - 10.0 4.6
MSW(g)
[ED.sub.01] 480 551 106 53
[MOE.sub.01](50) 9.6 11.0 2.1 1.1
[ED.sub.05] 1,089 - 544 273
[MOE.sub.05](50) 21.8 - 10.9 5.5
(a) Dose transformation, dose effect, and age effect, respectively. (b) Log, linear, and quadratic. (c) [ED.sub.05] outside the observable range of data. (d) Log, linear, and spline. (e) Log, quadratic, and spline. (f) Sqrt, quadratic, and spline. (g) Identity, quadratic, and truncated. Table 10. Concentrations ([micro]g/L) for different measures of risk (southwestern Taiwanese comparison population).
Bladder Lung
Model no.(a) M F M F
4(b)
[ED.sub.01] 21 19 10 10
[LED.sub.01] 17 16 8 8
[MOE.sub.01](50) 0.4 0.4 0.2 0.2
[ED.sub.05] 649 452 768 522
[LED.sub.05] 422 313 403 312
[MOE.sub.05](50) 13.0 9.0 15.4 10.4
5(d)
[ED.sub.01] 54 25 76 27
[LED.sub.01] 21 12 22 9
[MOE.sub.01](50) 1.1 0.5 1.5 0.5
[ED.sub.05] 723 464 780 520
[LED.sub.05] 508 315 558 362
[MOE.sub.05](50) 14.5 9.3 15.6 10.4
7(e)
[ED.sub.01] 156 136 79 76
[LED.sub.01] 131 117 62 63
[MOE.sub.01](50) 3.1 2.7 1.6 1.5
[ED.sub.05] 917 624 880 608
[LED.sub.05] 786 548 705 510
[MOE.sub.05](50) 18.3 12.5 17.6 12.2
8(f)
[ED.sub.01] 108 85 50 63
[LED.sub.01] 65 56 25 35
[MOE.sub.01](50) 2.2 1.7 1 1.3
[ED.sub.05] 817 536 778 582
[LED.sub.05] 594 406 489 431
[MOE.sub.05](50) 16.3 10.7 15.6 11.6
MSW
[ED.sub.01] 185 101 181 113
[MOE.sub.01](50) 3.7 2.0 3.6 2.3
[ED.sub.05] 959 520 936 583
[MOE.sub.05](50) 19.2 10.4 18.7 11.7
Liver Combined
Model no.(a) M F M F
4(b)
[ED.sub.01] 119 467 3 2
[LED.sub.01] 37 76 2 2
[MOE.sub.01](50) 2.4 9.3 0.1 0.0
[ED.sub.05] -(c) - 93 63
[LED.sub.05] - - 66 48
[MOE.sub.05](50) - - 1.9 1.3
5(d)
[ED.sub.01] 503 455 62 9
[LED.sub.01] 247 110 22 3
[MOE.sub.01](50) 10.1 9.1 1.2 0.2
[ED.sub.05] - - 330 132
[LED.sub.05] - - 226 79
[MOE.sub.05](50) - - 6.6 2.6
7(e)
[ED.sub.01] 309 485 21 20
[LED.sub.01] 174 242 17 17
[MOE.sub.01](50) 6.2 9.7 0.4 0.4
[ED.sub.05] - - 347 250
[LED.sub.05] - - 292 219
[MOE.sub.05](50) - - 6.9 5.0
8(f)
[ED.sub.01] 779 559 31 18
[LED.sub.01] 400 168 14 10
[MOE.sub.01](50) 15.6 11.2 0.6 0.4
[ED.sub.05] - - 416 238
[LED.sub.05] - - 275 167
[MOE.sub.05](50) - - 8.3 4.8
MSW
[ED.sub.01] 709 597 98 55
[MOE.sub.01](50) 14.2 11.9 2.0 1.1
[ED.sub.05] 1,608 - 506 284
[MOE.sub.05](50) 32.2 - 10.1 5.7
(a) Dose transformation, dose effect, and age effect, respectively. (b) Log, linear, and quadratic. (c) [ED.sub.01] outside the observable range of data. (d) Log, quadratic, and quadratic. (e) Sqrt, linear, and quadratic. (f) Sqrt, quadratic, and quadratic. Discussion In contrast to the 1988 EPA risk assessment that focused on skin cancer incidence (4), this study examines cancer mortality in a setting where exposure is measured at village level. Although there is an advantage to having individual village measurements, there also appears to be variability in the exposure assessment, causing high variability in the risk estimates. Depending on the model and whether or not a comparison population is used in the analysis, [ED.sub.01] estimates range in value from 21 to 633 [micro]g/L for male bladder cancer. For males, the lung cancer risk tends to be slightly higher than the risk for bladder cancer, with [ED.sub.01] values ranging from 10 to 364 [micro]g/L. Although this result seems in contrast to the high SMRs for bladder cancer in Table 5, the risk estimates are calculated on an additive scale and are influenced by background cancer rates. Hence, even though bladder cancer has high SMRs, the number of excess bladder cancer deaths associated with exposure is only moderate because of the low bladder cancer death rate in the general population. In contrast, because lung cancer is more prevalent in the general population, even a moderate SMR can lead to high numbers of excess deaths. There does not appear to be high risk associated with liver cancer in males with the exception of estimates based on three models that used a log-transformation of exposure (models 3, 4, and 5). [ED.sub.01] estimates range from 309 to 895 [micro]g/L for models apart from the latter, which yields values that range from 199 to 254 [micro]g/L. The risk associated with female cancers tends to be higher than that of males for each cancer type. For bladder cancer, [ED.sub.01] estimates for females range from 17 to 365 [micro]g/L. For lung and liver cancer, female [ED.sub.01] estimates range from 8 to 396 [micro]g/L and 331 to 824 [micro]g/L, respectively. The best models according to AIC for bladder, lung, and liver cancer combined did not exactly correspond to the models presented in Tables 8-10. For males, the best model with no comparison population is model 1, which has a linear untransformed dose effect and a quadratic age effect (Table 8). For females the best model for combined cancer has a square root transformation on dose with a quadratic dose and age effect. The [ED.sub.01] estimate based on this model equals 844 [micro]g/L. When a comparison population is used (either all of Taiwan or the southwestern region of Taiwan), the best model for both males and females has a square root transformation on dose with a linear dose effect and spline age effect. [ED.sub.01] estimates based on this model with the entire Taiwanese population equal 22 and 18 [micro]g/L for males and females, respectively. When the southwestern region was used, [ED.sub.01] estimates equal 21 and 20 [micro]g/L for males and females, respectively. Our results show that exposure-response assessments depend highly on the choice of model, as well as whether or not a comparison population is used in the analysis. As discussed by Morales et al. (10), one possible explanation is the uncertainty associated with an ecologic study design. We assumed the same arsenic concentration for all persons in the same village and individual exposures can vary widely in a village. Mortality records are available for individuals, but their individual exposures are not. The National Academy of Sciences (1) provides a good discussion on this subject. Although one might argue that the appropriate strategy would be to select the best model based on accepted statistical criteria, several models gave essentially the same quality fit (as measured by AIC), yet yielded substantial differences in risk estimates. For example, for the models without a comparison population, the MSW model gave a fit comparable to some of the GLM models, but produced [ED.sub.01] estimates almost twice as high. Despite the comparably good fit, we preferred the GLM models to the MSW model. For example, sensitivity analysis revealed that the MSW model was influenced strongly by the removal of various subsets of villages, whereas the GLM was not (10). The poor nutritional status of the Taiwanese in the Blackfoot disease region could be another contributing factor of uncertainty. We could not account for dietary intake of inorganic arsenic in food for either population, or for other confounders in this analysis. Differences in [ED.sub.01] estimates were particularly affected by whether or not a comparison population was used. There is reason to believe that the urban Taiwanese population is not a comparable population for the poor rural population used in this study. Thus, risk estimates using the Taiwanese population may be biased. As an alternative, we used the southwestern region of Taiwan; we found very different risk estimates based on the two different comparison populations (Tables 9 and 10). We could have done other analyses. For example, we could have calculated lifetime death rates for the unexposed group [ldr(0)] using U.S. population data. It would be of interest to see how the unexposed death rates in the United States compare to the death rates in Taiwan. Despite the considerable variation in estimated [ED.sub.01], the results are sobering so·ber adj. so·ber·er, so·ber·est 1. Habitually abstemious in the use of alcoholic liquors or drugs; temperate. 2. Not intoxicated or affected by the use of drugs. 3. and indicate that current standards are not adequately protective against cancer. For the combined analysis with no comparison population and identity transformation on dose, the [MOE.sub.01](50) values range from 0.4 to 16.9 for both males and females. When we include a comparison population, the [MOE.sub.01](50) values range from 0.2 to 3.4. The current arsenic standard of 50 [micro]g/L (4) is actually below the estimated [ED.sub.01], which suggests that the risk at the current standard is higher than 1 in 100. Note, however, this estimate is likely to be overly conservative because the data suggest that the log-transformations lead to somewhat unstable results. Even considering the identity transformation, which tended to give less extreme results, the risk associated with a concentration of 50 [micro]g/L is approximately 1 in 300, based on linear extrapolation (mathematics, algorithm) extrapolation - A mathematical procedure which estimates values of a function for certain desired inputs given values for known inputs. If the desired input is outside the range of the known values this is called extrapolation, if it is inside then from the point of departure. Risks of a similar magnitude were reported by Smith et al. (27). This is an extremely high value. We could argue that if indeed the risk were this high, we would expect to find epidemiologic evidence even within the U.S. population. The SEER Cancer Statistics Review (28) estimates that the age-adjusted U.S. mortality rates for bladder, lung, and liver cancer are 3.2, 49.5, and 2.8 per 100,000, respectively. It is also estimated that approximately 5% of large and small regulated water supply systems in the United States have arsenic concentrations [is greater than] 20 [micro]g/L (29). Thus, if the excess cancer risk associated with 50 [micro]g/L arsenic is on the order of magnitude A change in quantity or volume as measured by the decimal point. For example, from tens to hundreds is one order of magnitude. Tens to thousands is two orders of magnitude; tens to millions is three orders of magnitude, etc. 1 in 1,000, we would expect an increase of approximately 0.05 per 1,000 or 5 per 100,000 in the population. It is not surprising that epidemiologic studies in the United States have not so far been able to identify clear associations. Thus, we conclude that arsenic in drinking water may indeed be contributing to excess cancer mortality in the United States. REFERENCES AND NOTES (1.) National Research Council. Arsenic in Drinking Water. Washington, DC:National Academy Press, 1999. (2.) U.S. EPA. Health Assessment Document for Inorganic Arsenic. EPA 600/8-63/021F. Cincinnati, OH:U.S. Environmental Protection Agency, 1984. (3.) Tseng WP, Chu HM, How SW, Fong JM, Lin CS, Yeh S. Prevalence of skin cancer in an endemic area Endemic area A geographical region where a particular disease is prevalent. Mentioned in: Leprosy, Scrub Typhus of chronic arsenicism in Taiwan. J Natl Cancer Inst 40:453-463 (1968). (4.) U.S. EPA. Special Report of Inorganic Arsenic: Skin Cancer; Nutritional Essentiality. EPA 625/3-87/013. Washington, DC:U.S. Environmental Protection Agency, 1988. (5.) Safe Drinking Water Act Amendments. 42 U.S.C. 300g-1 (b) (12) (A)(iv), 1996. (6.) Smith AH, Goycolea M, Haque R, Biggs ML. Marked increase in bladder and lung cancer mortality in a region of northern Chile due to arsenic in drinking water. Am J Epidemiol 147:660-669 (1998). (7.) Hopenhayn-Rich C, Biggs ML, Fuchs A, Bergoglio R, Tello EE, Nicolli H, Smith AH. Bladder cancer mortality associated with arsenic in drinking water in Argentina. Epidemiology epidemiology, field of medicine concerned with the study of epidemics, outbreaks of disease that affect large numbers of people. Epidemiologists, using sophisticated statistical analyses, field investigations, and complex laboratory techniques, investigate the cause 7:117-124 (1996). (8.) Chen CJ, Chuang YC, Lin TM, Wu HY. Malignant malignant /ma·lig·nant/ (-nant) 1. tending to become worse and end in death. 2. having the properties of anaplasia, invasiveness, and metastasis; said of tumors. neoplasms among residents of a Blackfoot disease-endemic area in Taiwan: high-arsenic artesian well artesian well, deep drilled well through which water is forced upward under pressure. The water in an artesian well flows from an aquifer, which is a layer of very porous rock or sediment, usually sandstone, capable of holding and transmitting large quantities of water and cancers. Cancer Res 45:5895-5899 (1985). (9.) Brown KG. Assessing risk of inorganic arsenic in drinking water in the United States. Hum hum (hum) a low, steady, prolonged sound. venous hum a continuous blowing, singing, or humming murmur heard on auscultation over the right jugular vein in the sitting or erect position; it is Ecol Risk Assess 4:1061-1070 (1998). (10.) Morales KH, Ryan L, Brown KG, Kuo TL, Chen CJ, Wu MM. Model sensitivity in an analysis of arsenic exposure and bladder cancer in southwestern Taiwan. In: Proceedings of the Third International Conference on Arsenic Exposure and Health Effects, 12-15 July 1996, San Diego, California “San Diego” redirects here. For other uses, see San Diego (disambiguation). San Diego is a coastal Southern California city located in the southwestern corner of the continental United States. As of 2006, the city has a population of 1,256,951. . New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of :Elsevier, 1999;207-215. (11.) Chen CJ, Kuo TL, Wu MM. Arsenic and cancers [Letter]. Lancet lancet /lan·cet/ (lan´set) a small, pointed, two-edged surgical knife. lan·cet n. ii:414-415 (1988). (12.) Wu MM, Kuo TL, Hwang YH, Chen CJ. Dose-response relation between arsenic concentration in well water and mortality from cancers and vascular diseases vascular diseases, n.pl diseases of the peripheral circulatory system. . Am J Epidemiol 130:1123-1132 (1989). (13.) Chen CJ, Chen CW, Wu MM, Kuo TL. Cancer potential in liver, lung, bladder and kidney due to ingested in·gest tr.v. in·gest·ed, in·gest·ing, in·gests 1. To take into the body by the mouth for digestion or absorption. See Synonyms at eat. 2. inorganic arsenic in drinking water. Br J Cancer 66:888-892 (1992). (14.) WHO. International Classification of Diseases: Manual of the International Statistical Classification of Diseases, Injuries, and Causes of Death, 1965 Revision, Vol 1 and 2. Geneva Geneva, canton and city, Switzerland Geneva (jənē`və), Fr. Genève, canton (1990 pop. 373,019), 109 sq mi (282 sq km), SW Switzerland, surrounding the southwest tip of the Lake of Geneva. :World Health Organization, 1967. (15.) Chen KP, Wu HY, Wu TC. Epidemiologic studies on Blackfoot disease in Taiwan. 3: physicochemical physicochemical /phys·i·co·chem·i·cal/ (fiz?i-ko-kem´ik-il) pertaining to both physics and chemistry. phys·i·co·chem·i·cal adj. 1. Relating to both physical and chemical properties. characteristics of drinking water in endemic endemic /en·dem·ic/ (en-dem´ik) present or usually prevalent in a population at all times. en·dem·ic adj. 1. Blackfoot disease areas. Mem Coll Med Natl Taiwan Univ 8:115-129 (1962). (16.) Yeh SJ, Yang yang (yang) [Chinese] in Chinese philosophy, the active, positive, masculine principle that is complementary to yin; see yin, under principle. MH. Preliminary report on trace element content in water samples from the Blackfoot disease endemic area and in biopsy biopsy (bīäp`sē), examination of cells or tissues removed from a living organism. Excised material may be studied in order to diagnose disease or to confirm findings of normality. samples from Blackfoot disease patients. In: Report on Blackfoot Disease Research, Vol. 8. Taichung, Taiwan:Taiwan Provincial Department of Health, 1980;22-28. (17.) Breslow NE, Day NE. Statistical Methods in Cancer Research. Vol II: The Design and Analysis of Cohort Studies A cohort study is a form of longitudinal study used in medicine and social science. It is one type of study design. In medicine, it is usually undertaken to obtain evidence to try to refute the existence of a suspected association between cause and disease; failure to refute . New York:Oxford University Press, 1987. (18.) Department of Health. Health Statistics. Vol II: Vital Statistics, 1973-1986. Taipei, Taiwan:Department of Health, 1974-1987. (19.) Venebles WN, Ripey BD. Modern Applied Statistics with S-PLUS. New York:Springer-Verlag, 1994. (20.) Vital Statistics of the United States, 1996. Hyattsville, MD:National Center for Health Statistics National Center for Health Statistics (NCHS) is part of the Centers for Disease Control and Prevention (CDC), which is part of the United States Department of Health and Human Services. NCHS is the United States' principal health statistics agency. , 1996. (21.) Smith AH, Sharp DS. A standardized standardized pertaining to data that have been submitted to standardization procedures. standardized morbidity rate see morbidity rate. standardized mortality rate see mortality rate. benchmark approach to the use of cancer epidemiology data for risk assessment. Toxicol Ind Health 1:205-212 (1985). (22.) U.S. Environmental Protection Agency. Proposed guidelines for carcinogen risk assessment; notice. Fed Reg FED REG Federal Register 61:17959-18011 (1996). (23.) Stuart A, Ord K. Kendall's Advanced Theory of Statistics. Vol 1: Distribution Theory. London:Edward Arnold Edward Arnold can refer to:
(24.) Efron B, Tibshirani RJ. An Introduction to the Bootstrap. New York:Chapman & Hall, 1993. (25.) Hastie TJ, Tibshirani RJ. Generalized Additive Models In statistics, the generalized additive model (or GAM) is a statistical model developed by Trevor Hastie and Rob Tibshirani blending properties of multiple regression (a special case of general linear model) with additive models. . New York:Chapman & Hall, 1990. (26.) Hosmer DW, Lemeshow S. Applied Logistic Regression. New York:John Wiley John Wiley may refer to:
(27.) Smith AH, Hopenhayn-Rich C, Bates Bates , Katherine Lee 1859-1929. American educator and writer best known for her poem "America the Beautiful," written in 1893 and revised in 1904 and 1911. MN, Goeden HM, Hertz-Picciotto I, Duggan HM, Wood R, Kosnett MJ, Smith MT. Cancer risks from arsenic in drinking water. Environ Health Perspect 97:259-267 (1992). (26.) Ries LAG, Kosary CL, Hankey BF, Miller BA, Clegg L, Edwards BK, eds. SEER Cancer Statistics Review, 1973-1996. Bethesda, MD:National Cancer Institute, 1999. (29.) Welch Welch , William Henry 1850-1934. American pathologist and bacteriologist who discovered the bacteria that causes gas gangrene. AH, Helsel DR, Focazio MJ, Watkins SA. Arsenic in ground water supplies of the United States. In: Proceedings of the Third International Conference on Arsenic Exposure and Health Effects, 12-15 July 1998, San Diego San Diego (săn dēā`gō), city (1990 pop. 1,110,549), seat of San Diego co., S Calif., on San Diego Bay; inc. 1850. San Diego includes the unincorporated communities of La Jolla and Spring Valley. Coronado is across the bay. , CA. New York:Elsevier, 1999;9-17. Knashawn H. Morales,(1) Louise Ryan,(1),(2) Tsung-Li Kuo,(3) Meei-Maan Wu,(4) and Chien-Jen Chen(5) (1) Department of Biostatistics biostatistics /bio·sta·tis·tics/ (-stah-tis´tiks) biometry. bi·o·sta·tis·tics n. The science of statistics applied to the analysis of biological or medical data. , Harvard School of Public Health The Harvard School of Public Health is (colloquially, HSPH) is one of the professional graduate schools of Harvard University. Located in Longwood Area of the Boston, Massachusetts neighborhood of Mission Hill, next to Harvard Medical School and Cambridge, Massachusetts, , Boston, Massachusetts “Boston” redirects here. For other uses, see Boston (disambiguation). Boston is the capital and most populous city of Massachusetts.[3] The largest city in New England, Boston is considered the unofficial economic and cultural center of the entire New , USA; (2) Dana-Farber Cancer Institute, Boston, Massachusetts, USA; (3) Department of Forensic Medicine forensic medicine: see medical jurisprudence. forensic medicine Science of applying medical knowledge to legal questions, recognized as a specialty since the early 19th century. Its primary tool has always been the autopsy, to identify the dead (e.g. , College of Medicine, National Taiwan University National Taiwan University (Traditional Chinese: 國立臺灣大學; Simplified Chinese: 国立台湾大学 , Taipei, Taiwan; (4) Institute of Biomedical Sciences The Institute of Biomedical Science (IBMS) is the professional body for biomedical scientists in the United Kingdom. It aims to promote and develop biomedical science and its practitioners. , Academia Sinica
The Academia Sinica (Chinese: 中央研究院; Pinyin: , Taipei, Taiwan; (5) Graduate Institute of Epidemiology, National Taiwan University, Taipei, Taiwan Address correspondence to L. Ryan, Department of Biostatistics, Dana-Farber Cancer Institute, 44 Binney Street, Boston, MA 02115 USA. Telephone: (617) 632-3602. Fax: (617) 632-2444. E-mail: ryan@jimmy.harvard.edu Support was received from the National Institutes of Health (grants 5F31GM18906, ES0002, and CA48061), the David and Lucile Packard Foundation David and Lucile Packard Foundation, private philanthropic institution that funds nonprofit organizations. It was founded in 1964 by David Packard (1912–96), co-founder of Hewlett-Packard Co., and his wife Lucile (1914–87). , and the Department of Health, Executive Yuan The Executive Yuan (Traditional Chinese: 行政院; Pinyin: Xíngzhèng Yuàn; literally "Executive court") is the executive branch of the government of the Republic of China. , ROC (DOH88-HR-503). Received 29 December 1999; accepted 14 March 2000. |
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